LM2794TLX National Semiconductor, LM2794TLX Datasheet - Page 13

LM2794TLX

Manufacturer Part Number

LM2794TLX

Description

IC LED DRVR WHT BCKLT 14USMD

Manufacturer

National Semiconductor

Datasheet

1.LM2794TLX.pdf (16 pages)

Specifications of LM2794TLX

Constant Current

Yes

Topology

PWM, Switched Capacitor (Charge Pump), Step-Up (Boost)

Number Of Outputs

Internal Driver

Yes

Type - Primary

Backlight

Type - Secondary

White LED

Frequency

325kHz ~ 675kHz

Voltage - Supply

2.7 V ~ 5.5 V

Voltage - Output

3.8V

Mounting Type

Surface Mount

Package / Case

14-UFBGA

Operating Temperature

-30°C ~ 85°C

Current - Output / Channel

20mA

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Other names

*LM2794TLX

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Application Information

OUTPUT CURRENT CAPABILITY

The primary constraint on the total current capability is the

headroom voltage requirement of the internal current

sources. Combining the V

previous two sections yields the basic inequality for deter-

mining the validity of an LM2794/5 LED-drive application:

Rearranging this inequality shows the estimated total output

current capability of an application:

Examining the equation above, the primary limiting factors

on total output current capability are input and LED forward

voltage. A low input voltage combined with a high LED

voltage may result in insufficient headroom voltage across

the current sources, causing them to fall out of regulation.

When the current sources are not regulated, LED currents

will be below desired levels and brightness matching will be

highly dependent on LED forward voltage matching.

Typical LM2794/5 output resistance is 3.0Ω. For worst-case

design calculations, using an output resistance of 3.5Ω is

recommended. LM2794/5 has a typical k

20mV/mA. For worst-case design calculations, use k

25mV/mA. (Worst-case recommendations account for pa-

rameter shifts from part-to-part variation and apply over the

full operating temperature range). R

slightly with temperature, but losses are typically offset by

the negative temperature coefficient properties of LED for-

ward voltages. Power dissipation and internal self-heating

may also limit output current capability but is discussed in a

later section.

PARALLEL Dx OUTPUTS FOR INCREASED CURRENT

DRIVE

Outputs D

combination to drive higher currents through fewer LEDs.

For example in Figure 4, outputs D

together to drive one LED while D

together to drive a second LED.

TOTAL

1.5 x V

≤ [(1.5 x V

FIGURE 4. Two Parallel Connected LEDs

through D

POUT

− I

IN-MIN

TOTAL

= 1.5 x V

POUT

HR-MIN

) − V

may be connected together in any

− V

x R

POUT

= k

OUT

DX-MAX

− I

and V

≥ V

− V

TOTAL

x I

HR-MIN

− (k

OUT

and D

x R

≥ (k

equations from the

and k

(Continued)

OUT

x I

are connected

x I

constant of

)] ÷ R

increase

)

20028533

OUT

With this configuration, two parallel current sources of equal

value provide current to each LED. R

therefore be chosen so that the current through each output

is programmed to 50% of the desired current through the

parallel connected LEDs. For example, if 30mA is the de-

sired drive current for 2 parallel connected LEDs , R

the outputs is 15mA. Other combinations of parallel outputs

may be implemented in similar fashions, such as in Figure 5.

Connecting outputs in parallel does not affect internal opera-

tion of the LM2794/95 and has no impact on the Electrical

Characteristics and limits previously presented. The avail-

able diode output current, maximum diode voltage, and all

other specifications provided in the Electrical Characteristics

table apply to parallel output configurations, just as they do

to the standard 4-LED application circuit.

THERMAL PROTECTION

When the junction temperature exceeds 150˚C (typ.), the

LM2794/5 internal thermal protection circuitry disables the

part. This feature protects the device from damage due to

excessive power dissipation. The device will recover and

operate normally when the junction temperature falls below

140˚C (typ.). It is important to have good thermal conduction

with a proper layout to reduce thermal resistance.

POWER EFFICIENCY

Figure 6 shows the efficiency of the LM2794/5. The change

in efficiency shown by the graph comes from the transition

from Pass Mode to a gain of 1.5.

Efficiency (E) of the LM2794/5 is defined here as the ratio of

the power consumed by LEDs (P

from the input source (P

quiescent current of the LM2794/5, I

through one LED, V

current, and N is the number of LEDs connected to the

regulated current outputs. In the input power calculation, the

1.5 represents the switched capacitor gain configuration of

the LM2794/5.

BRGT

should be selected so that the current through each of

FIGURE 5. One Parallel Connected LED

= V

LED

= N x V

x (1.5 x N x I

is the forward voltage at that LED

). In the equations below, I

= V

LED

x I

LED

x I

LED

SET

) to the power drawn

LED

is the current flowing

+ I

and V

)

BRGT

www.national.com

SET

should

is the

20028534

and

LM2794TLX National Semiconductor, LM2794TLX Datasheet - Page 13

LM2794TLX

Specifications of LM2794TLX

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